Chapter 1 The Study of Body Function Lecture PowerPoint

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Chapter 1 The Study of Body Function Lecture PowerPoint Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

I. Introduction to Physiology

What Is Physiology? Study of biological functions: how the body works Concerns the normal functions of cells, tissues, organs, and systems Emphasizes mechanisms Is derived from scientific experiments

II. Homeostasis and Feedback Control

Homeostasis Term coined by Walter Cannon in 1932 Homeostasis is constancy of the internal environment. The main purpose of our physiological mechanisms is to maintain homeostasis. Deviation from homeostasis indicates disease. Homeostasis is accomplished most often by negative feedback loops.

Negative Feedback Loops Involve: Sensors in the body to detect change and send information to the: Integrating center, which assesses change around a set point. The integrating center then sends instructions to an: Effector, which can make the appropriate adjustments.

Negative Feedback Loops

Negative Feedback Loops Body temperature: Sensors in the brain detect deviation from 37ºC. Another part of the brain assesses this as actionable, and effectors (sweat glands) are stimulated to cool the body. Once the body is cool, sensors alert the integrating center, and sweat glands are inhibited. The end result regulates the entire process. Production of the end product shuts off or down-regulates the process. This is why it is called a negative feedback loop.

Antagonistic Effectors Homeostasis is often maintained by opposing effectors that move conditions in opposite directions. This maintains conditions within a certain normal range, or dynamic constancy. When you are hot, you sweat; when you are cold, you shiver. These are antagonistic reactions.

Antagonistic Effectors Figure 1.3 Figure 1.4

Quantitative Measurements A knowledge of normal ranges aids in diagnosing diseases and in assessing the effects of drugs and other treatments in experiments.

Quantitative Measurements

Positive Feedback The end product in a process stimulates the process. Positive feedback could not work alone, but it does contribute to many negative feedback loops. For example, if a blood vessel is damaged, a process is begun to form a clot. Once the damage is fixed, clotting ends (negative feedback). However, the process of forming the clot involves positive feedback. The strength of uterine contractions during childbirth is also regulated by a positive feedback loop.

Intrinsic and Extrinsic Regulation Regulation of processes within organs can occur in two ways: Intrinsically: Cells within the organ sense a change and signal to neighboring cells to respond appropriately. Extrinsically: The brain (or other organs) regulates an organ using the endocrine or nervous system.

Neural and Endocrine Regulation The nervous system “innervates” organs with nerve fibers. The endocrine system releases hormones into the blood, which transports them to multiple target organs.

Neural and Endocrine Regulation

Feedback Control of Hormone Secretions Hormones are secreted in response to specific stimuli. An increase in blood sugar results in the release of insulin, which removes sugar from the blood. Secretion can be inhibited by its own effects. Decreased blood sugar inhibits the release of insulin. This is an example of negative feedback inhibition.

Feedback Control of Hormone Secretions Negative feedback inhibition usually involves an antagonist to make sure homeostasis is maintained within normal levels. When blood sugar is low, the hormone glucagon is secreted, which results in a rise in blood sugar. (We will discuss more about hormones and control in Chapter 11)

Feedback Control of Hormone Secretions

III. The Primary Tissues

The Primary Tissues Our organs are composed of four major categories of tissues: Muscle tissue Nervous tissue Epithelial tissue Connective tissue Each tissue has particular structures and functions that dictate the physiology of the organ.

Muscle Tissue Specialized for contraction The three types are: Skeletal muscle Cardiac muscle Smooth muscle

Skeletal Muscle Tissue Voluntary muscle (muscle you can consciously control) Associated with bones that are pulled to produce movements The tongue, esophagus, sphincters, and diaphragm are also skeletal muscle. Has cells organized in striations

Skeletal Muscle Tissue

Cardiac Muscle Tissue Found only in the heart Striated, but very different in structure and action from skeletal muscle. Intercalated discs allow passage of sodium ions between cells. Involuntary muscle (muscle you cannot consciously control)

Cardiac Muscle Tissue

Smooth Muscle Tissue Found in the walls of digestive, urinary, and reproductive organs, blood vessels, and bronchioles of the lungs Not striated Involuntary

Smooth Muscle Tissue

Nervous Tissue Found in the brain, spinal cord, and nerves Composed of neurons and glial cells, which support the neurons Neurons conduct impulses and have three parts: Dendrites: receive signal Axon: sends signal Cell body: metabolic center

Nervous Tissue

Epithelial Tissue Forms the membranes that line /cover body surfaces as well as glands Epithelial membranes are classified by the number of layers: Simple epithelium has one layer and is specialized for transport of substances. Stratified epithelium is composed of multiple layers and provides protection.

Epithelial Tissues Epithelial tissues are also classified by the shape of their cells: Squamous: flattened cells Cuboidal: as tall as they are long Columnar: tall cells (Columnar tissues have goblet cells that secrete mucus and cilia that move in a coordinated fashion.)

Epithelial Tissues

Simple Epithelial Tissues Cuboidal Simple Squamous Simple Columnar Note that the tissue beneath the basement membrane is connective tissue

Stratified Epithelial Tissue To provide protection, cells of stratified epithelial tissues are held together by structures called junctional complexes. (Chapter 6) These are too close together to house blood vessels, so are nourished by connective tissues beneath. Epithelial tissues are attached to connective tissues by a basement membrane.

Junctional Complexes Tight junctions: where the membranes of the 2 cells actually join together. This does not allow easy diffusion between the cells. Adherens junctions: where the membranes of the 2 cells are very close together and joined by intercellular “glue” Desmosomes: where the membranes of the 2 cells are “buttoned” together my interactions between desmosomal proteins

Types Junctional Complexes

Stratified Epithelial Tissue The epidermis is stratified, squamous, keratinized epithelium. It is avascular and has to be supported by blood vessels located in the loose connective tissue of the dermis.

Stratified Epithelial Tissue

Exocrine Glands Derived from epithelial tissues Secretions are transported by ducts. Examples include lacrimal, sweat, and sebaceous glands; digestive enzyme glands; and the prostate.

Exocrine Glands Exocrine glands will retain a duct that can carry their secretion to the surface of the epithelial membrane, whereas endocrine glands are ductless and secrete their product into neighboring blood vessels.

Connective Tissues Characterized by a matrix made up of protein fibers and extracellular material There are four major categories: Connective tissue proper Cartilage Bone Blood

Connective Tissue Proper Composed of protein fibers and a gel-like ground substance Subtypes: Loose: collagen fibers scattered loosely with room for blood vessels and nerves Example: upper layer of the dermis of the skin Dense regular: Densely packed collagen fibers with little room for ground substance Examples: tendons and ligaments

Connective Tissue Proper

Connective Tissue Proper Subtypes: Adipose tissue stores fat. Dense irregular connective tissue is composed of densely packed collagen fibers in various arrangements to resist forces.

Connective Tissue Proper

Cartilage Connective Tissue Composed of cells called chondrocytes surrounded by a semisolid ground substance Serves as a template skeleton during bone development Found in joints to provide a gliding surface for bones

Bone Cells called osteoblasts trap mineral salts, forming concentric layers of calcified material around a canal filled with blood vessels and nerves.

Bone

IV. Organs and Systems

Organs An organ is composed of two or more tissues that serve different functions in the organ. The skin is the largest organ in the body. The skin has all four primary tissues.

Organs

Tissue Development Tissues are composed of highly specialized cells that arise from three embryonic germ layers: Endoderm Mesoderm Ectoderm

Stem Cells Zygotes are totipotent, which means their cells can become any type of cell. These are true stem cells. As cells begin to differentiate, a few adult stem cells are retained to allow for cell replacement. Adult stem cells are still limited to a narrow range of possibilities but can become several related cells and thus are called multipotent. Bone marrow cells can become any type of blood cell.

Systems Organs that perform related functions are grouped into systems.

Systems

Body Fluid Compartments Intracellular: area inside the cells Extracellular: area outside the cells Examples: blood plasma and interstitial fluid Both body fluid compartments are filled primarily with water and are separated by membranes.